DocumentCode
2303611
Title
Light-harvesting semiconductor quantum dot nanocrystals integrated on photovoltaic radial junction nanopillars
Author
Guzelturk, Burak ; Mutlugun, Evren ; Wang, Xiadong ; Pey, Kin Leong ; Demir, Hilmi Volkan
Author_Institution
Inst. of Mater. Sci. & Nanotechnol., UNAM, Turkey
fYear
2010
fDate
7-11 Nov. 2010
Firstpage
357
Lastpage
358
Abstract
In the last decades increased awareness for environmental problems, climate change, and limited energy sources has escalated research efforts around the globe to investigate photovoltaics as an alternative energy source. The sun offers an enormous potential for solar energy conversion, which makes photovoltaics quite attractive among green energy sources. However, there is still not an ultimate photovoltaic device which yet provides high efficiencies at low costs. Recently with the development of nanofabrication technologies, nanostructured solar cells have emerged at research labs (e.g., using nanowires, nanorods, nanotubes etc.). These nanostructured device architectures are intended to yield enhanced optical properties such as light trapping compared to existing planar devices. In certain architectures, however, there are some nanofabrication bottlenecks that adversely affect the overall device performance of such nanostructured photovoltaics. These technical challenges can possibly be overcome with maturing fabrication methods in time. But, there also exist limitations stemming from intrinsic properties of the active materials that cannot be easily fixed unless hybrid approaches are exploited or materials are replaced. For example, silicon, which is the most commonly used material in photovoltaic industry, suffers too strong absorption at short wavelengths (i.e., UV-blue), undesirably leading to poor performance in this spectral range due to high front surface recombination rates. However, UV-blue portion constitutes almost 10% of the sunlight, which is mostly unused by Si based photovoltaics. To address this problem, we propose and demonstrate light-trapping radial p-n junction Si nanopillar solar cells that are furnished with CdSe quantum dot nanocrystals to harvest short-wavelength radiation in addition to long-wavelengths. The basic operating principle of these light-harvesting nanocrystals integrated on nanopillars relies on the wavelength up-conversion ide- - a of incident photon absorption in these nanocrystals at short wavelengths and subsequent photon emission at longer wavelengths, which is in turn reabsorbed by the furnished nanopillar diodes. Although such light-harvesters were previously studied on planar devices or those with elliptical holes in them, nanocrystal-decorated nanopillars have not been investigated to date. Here we demonstrate that this nanopillar architecture provides additional advantage of trapping photon emission from the light-harvesting nanocrystals for wavelength up-conversion, compared to the planar case.
Keywords
II-VI semiconductors; cadmium compounds; elemental semiconductors; energy harvesting; integrated optics; nanophotonics; nanostructured materials; p-n junctions; photoexcitation; semiconductor diodes; semiconductor quantum dots; silicon; solar cells; wide band gap semiconductors; Si-CdSe; elliptical holes; light-harvesting semiconductor quantum dot nanocrystals; light-trapping radial p-n junction nanopillar solar cells; nanocrystal-decorated nanopillars; nanopillar diodes; optical integration; photon absorption; photon emission; photovoltaic radial junction nanopiliars; planar devices; short-wavelength radiation; wavelength upconversion;
fLanguage
English
Publisher
ieee
Conference_Titel
IEEE Photonics Society, 2010 23rd Annual Meeting of the
Conference_Location
Denver, CO
ISSN
-
Print_ISBN
978-1-4244-5368-9
Electronic_ISBN
-
Type
conf
DOI
10.1109/PHOTONICS.2010.5698907
Filename
5698907
Link To Document